[1]	AhmedSM, LiuP, XueQ, JiC, QiT, GuoJ, GuoJ, KangZ. TaDIR1-2, a wheat ortholog of lipid transfer protein AtDIR1 contributes to negative regulation of wheat resistance against Puccinia striiformis f. sp. tritici. Front Plant Sci, 2017, 8: 521 CrossRef Google scholar

[2]	AlvesMS, DadaltoSP, GoncalvesAB, de SouzaGB, BarrosVA, FiettoLG. Transcription factor functional protein-protein interactions in plant defense responses. Proteomes, 2014, 2: 85-106 CrossRef Google scholar

[3]

BaoD, GanbaatarO, CuiX, YuR, BaoW, FalkBW, WuriyanghanH. Down-regulation of genes coding for core RNAi components and disease resistance proteins via corresponding microRNAs might be correlated with successful soybean mosaic virus infection in soybean. Mol Plant Pathol, 2018, 19: 948-960 CrossRef Google scholar

[4]	BaulcombeD. RNA silencing in plants. Nature, 2004, 431: 356-363 CrossRef Google scholar

[5]	BeckerA, LangeM. VIGS – genomics goes functional. Trends Plant Sci, 2010, 15: 1-4 CrossRef Google scholar

[6]	BolognaNG, VoinnetO. The diversity, biogenesis, and activities of endogenous silencing small RNAs in Arabidopsis. Annu Rev Plant Biol, 2014, 65: 473-503 CrossRef Google scholar

[7]	BorgesF, MartienssenRA. The expanding world of small RNAs in plants. Nat Rev Mol Cell Biol, 2015, 16: 727-741 CrossRef Google scholar

[8]	BorrelliGM, MazzucotelliE, MaroneD, CrosattiC, MichelottiV, ValèG, MastrangeloAM. Regulation and evolution of NLR genes: a close interconnection for plant immunity. Int J Mol Sci, 2018, 19: 1662 CrossRef Google scholar

[9]	CaiQ, HeB, JinH. A safe ride in extracellular vesicles - small RNA trafficking between plant hosts and pathogens. Curr Opin Plant Biol, 2019, 52: 140-148 CrossRef Google scholar

[10]	CaiQ, HeB, KogelKH, JinH. Cross-kingdom RNA trafficking and environmental RNAi-nature's blueprint for modern crop protection strategies. Curr Opin Microbiol, 2018, 46: 58-64 CrossRef Google scholar

[11]	CaiQ, QiaoL, WangM, HeB, LinFM, PalmquistJ, HuangSD, JinH. Plants send small RNAs in extracellular vesicles to fungal pathogen to silence virulence genes. Science, 2018, 360: 1126-1129 CrossRef Google scholar

[12]

CampoS, Peris-PerisC, SiréC, MorenoAB, DonaireL, ZytnickiM, NotredameC, LlaveC, San SegundoB. Identification of a novel microRNA (miRNA) from rice that targets an alternatively spliced transcript of the Nramp6 (natural resistance-associated macrophage protein 6) gene involved in pathogen resistance. New Phytol, 2013, 199: 212-227 CrossRef Google scholar

[13]	Campo S, Sánchez-Sanuy F, Camargo-Ramírez R, Gómez-Ariza J, Baldrich P, Campos-Soriano L, Soto-Suárez M, Segundo BS (2021) A novel transposable element-derived microRNA participates in plant immunity to rice blast disease. Plant Biotechnol J. https://doi.org/10.1111/pbi.13592

[14]	Canto-PastorA, BamcS, ValliAA, SummersW, SchornackS, BaulcombeDC. Enhanced resistance to bacterial and oomycete pathogens by short tandem target mimic RNAs in tomato. Proc Natl Acad Sci U S A, 2019, 116: 2755-2760 CrossRef Google scholar

[15]	CarbonellA, CarringtonJC. Antiviral roles of plant ARGONAUTES. Curr Opin Plant Biol, 2015, 27: 111-117 CrossRef Google scholar

[16]	CarbonellA, LisónP, DaròsJA. Multi-targeting of viral RNAs with synthetic trans-acting small interfering RNAs enhances plant antiviral resistance. Plant J, 2019, 100: 720-737 CrossRef Google scholar

[17]	CarraA, MicaE, GambinoG, PindoM, MoserC, PèME, SchubertA. Cloning and characterization of small non-coding RNAs from grape. Plant J, 2009, 59: 750-763 CrossRef Google scholar

[18]	CastelSE, MartienssenRA. RNA interference in the nucleus: roles for small RNAs in transcription, epigenetics and beyond. Nat Rev Genet, 2013, 14: 100-112 CrossRef Google scholar

[19]	ChanSW, ZilbermanD, XieZ, JohansenLK, CarringtonJC, JacobsenSE. RNA silencing genes control de novo DNA methylation. Science, 2004, 303: 1336 CrossRef Google scholar

[20]	ChandranV, WangH, GaoF, CaoXL, ChenYP, LiGB, ZhuY, YangXM, ZhangLL, ZhaoZX, ZhaoJH, WangYG, LiS, FanJ, LiY, ZhaoJQ, LiSQ, WangWM. miR396-OsGRFs module balances growth and rice blast disease-resistance. Front Plant Sci, 2018, 9: 1999 CrossRef Google scholar

[21]	ChenL, ChengX, CaiJ, ZhanL, WuX, LiuQ, WuX. Multiple virus resistance using artificial trans-acting siRNAs. J Virol Methods, 2016, 228: 16-20 CrossRef Google scholar

[22]	ChenX. Small RNAs and their roles in plant development. Annu Rev Cell Dev Biol, 2009, 25: 21-44 CrossRef Google scholar

[23]	ChitwoodDH, TimmermansMC. Small RNAs are on the move. Nature, 2010, 467: 415-419 CrossRef Google scholar

[24]	CooperB, CampbellKB. Protection against common bean rust conferred by a gene-silencing method. Phytopathology, 2017, 107: 920-927 CrossRef Google scholar

[25]	CuellarWJ, KreuzeJF, RajamäkiML, CruzadoKR, UntiverosM, ValkonenJP. Elimination of antiviral defense by viral RNase III. Proc Natl Acad Sci U S A, 2009, 106: 10354-10358 CrossRef Google scholar

[26]	CuiH, TsudaK, ParkerJE. Effector-triggered immunity: from pathogen perception to robust defense. Annu Rev Plant Biol, 2015, 66: 487-511 CrossRef Google scholar

[27]	CuiC, WangJ-J, ZhaoJ-H, FangY-Y, HeX-F, GuoH-S, DuanC-G. A Brassica miRNA regulates plant growth and immunity through distinct modes of action. Mol Plant, 2020, 13: 231-245 CrossRef Google scholar

[28]	CuiX, YanQ, GanS, XueD, DouD, GuoN, XingH. Overexpression of gma-miR1510a/b suppresses the expression of a NB-LRR domain gene and reduces resistance to Phytophthora sojae. Gene, 2017, 621: 32-39 CrossRef Google scholar

[29]	DanglJL, HorvathDM, StaskawiczBJ. Pivoting the plant immune system from dissection to deployment. Science, 2013, 341: 746-751 CrossRef Google scholar

[30]	DeanR, Van KanJA, PretoriusZA, Hammond-KosackKE, Di PietroA, SpanuPD, RuddJJ, DickmanM, KahmannR, EllisJ, FosterGD. The top 10 fungal pathogens in molecular plant pathology. Mol Plant Pathol, 2012, 13: 414-430 CrossRef Google scholar

[31]	DemirerGS, ZhangH, MatosJL, GohNS, CunninghamFJ, SungY, ChangR, AdithamAJ, ChioL, ChoMJ, StaskawiczB, LandryMP. High aspect ratio nanomaterials enable delivery of functional genetic material without DNA integration in mature plants. Nat Nanotechnol, 2019, 14: 456-464 CrossRef Google scholar

[32]	DengY, WangJ, TungJ, LiuD, ZhouY, HeS, DuY, BakerB, LiF. A role for small RNA in regulating innate immunity during plant growth. PLoS Pathog, 2018, 14 CrossRef Google scholar

[33]	DengY, ZhaiK, XieZ, YangD, ZhuX, LiuJ, WangX, QinP, YangY, ZhangG, LiQ, ZhangJ, WuS, MilazzoJ, MaoB, WangE, XieH, TharreauD, HeZ. Epigenetic regulation of antagonistic receptors confers rice blast resistance with yield balance. Science, 2017, 355: 962-965 CrossRef Google scholar

[34]	Deng YW, Ning YS, Yang DL, Zhai KR, Wang GL, He ZH (2020) Molecular basis of disease resistance and perspectives on breeding strategies for resistance improvement in crops. Mol Plant 13:1402–1419. https://doi.org/10.1016/j.molp.2020.09.018

[35]	DeversEA, BrosnanCA, SarazinA, AlbertiniD, AmslerAC, BrioudesF, JullienPE, LimP, SchottG, VoinnetO. Movement and differential consumption of short interfering RNA duplexes underlie mobile RNA interference. Nat Plants, 2020, 6: 789-799 CrossRef Google scholar

[36]	DuP, WuJ, ZhangJ, ZhaoS, ZhengH, GaoG, WeiL, LiY. Viral infection induces expression of novel phased microRNAs from conserved cellular microRNA precursors. PLoS Pathog, 2011, 7 CrossRef Google scholar

[37]	DunoyerP, SchottG, HimberC, MeyerD, TakedaA, CarringtonJC, VoinnetO. Small RNA duplexes function as mobile silencing signals between plant cells. Science, 2010, 328: 912-916 CrossRef Google scholar

[38]	FeiQ, XiaR, MeyersBC. Phased, secondary, small interfering RNAs in posttranscriptional regulatory networks. Plant Cell, 2013, 25: 2400-2415 CrossRef Google scholar

[39]	FeiQ, ZhangY, XiaR, MeyersBC. Small RNAs add zing to the zig-Zag-zig model of plant defenses. Mol Plant Microbe Interact, 2016, 29: 165-169 CrossRef Google scholar

[40]	FengH, ZhangQ, WangQ, WangX, LiuJ, LiM, HuangL, KangZ. Target of tae-miR408, a chemocyanin-like protein gene (TaCLP1), plays positive roles in wheat response to high-salinity, heavy cupric stress and stripe rust. Plant Mol Biol, 2013, 83: 433-443 CrossRef Google scholar

[41]	GasciolliV, MalloryAC, BartelDP, VaucheretH. Partially redundant functions of Arabidopsis DICER-like enzymes and a role for DCL4 in producing trans-acting siRNAs. Curr Biol, 2005, 15: 1494-1500 CrossRef Google scholar

[42]	GhildiyalM, ZamorePD. Small silencing RNAs: an expanding universe. Nat Rev Genet, 2009, 10: 94-108 CrossRef Google scholar

[43]	GonzálezVM, MüllerS, BaulcombeD, PuigdomènechP. Evolution of NBS-LRR gene copies among dicot plants and its regulation by members of the miR482/2118 superfamily of miRNAs. Mol Plant, 2015, 8: 329-331 CrossRef Google scholar

[44]	HeXF, FangYY, FengL, GuoHS. Characterization of conserved and novel microRNAs and their targets, including a TuMV-induced TIR-NBS-LRR class R gene-derived novel miRNA in Brassica. FEBS Lett, 2008, 582: 2445-2452 CrossRef Google scholar

[45]	HongW, QianD, SunR, JiangL, WangY, WeiC, ZhangZ, LiY. OsRDR6 plays role in host defense against double-stranded RNA virus, Rice dwarf Phytoreovirus. Sci Rep, 2015, 5: 11324 CrossRef Google scholar

[46]	HuG, HaoM, WangL, LiuJ, ZhangZ, TangY, PengQ, YangZ, WuJ. The cotton miR477-CBP60A module participates in plant defense against Verticillium dahlia. Mol Plant Microbe Interact, 2020, 33: 624-636 CrossRef Google scholar

[47]	HuangCY, WangH, HuP, HambyR, JinH. Small RNAs - big players in plant-microbe interactions. Cell Host Microbe, 2019, 26: 173-182 CrossRef Google scholar

[48]	Ji HM, Mao HY, Li SJ, Feng T, Zhang ZY, Cheng L, Luo SJ, Borkovich KA, Ouyang SQ (2021) Fol-milR1, a pathogenicity factor of Fusarium oxysporum, confers tomato wilt disease resistance by impairing host immune responses. New Phytol. https://doi.org/10.1111/nph.17436

[49]	JiangG, LiuD, YinD, ZhouZ, ShiY, LiC, ZhuL, ZhaiW. A rice NBS-ARC gene conferring quantitative resistance to bacterial blight is regulated by a pathogen effector-inducible miRNA. Mol Plant, 2020, 13: 1752-1767 CrossRef Google scholar

[50]	JiaoJ, PengD. Wheat microRNA1023 suppresses invasion of Fusarium graminearum via targeting and silencing FGSG_03101. J Plant Interact, 2018, 13: 514-521 CrossRef Google scholar

[51]	KageU, KarreS, KushalappaAC, McCartneyC. Identification and characterization of a fusarium head blight resistance gene TaACT in wheat QTL-2DL. Plant Biotechnol J, 2017, 15: 447-457 CrossRef Google scholar

[52]	Kalyandurg PB, Sundararajan P, Dubey M, Ghadamgahi F, Zahid MA, Whisson S, Vetukuri RR (2021) Spray-induced gene silencing as a potential tool to control potato late blight disease. Phytopathology. https://doi.org/10.1094/PHYTO-02-21-0054-SC

[53]	KarranRA, SanfaçonH. Tomato ringspot virus coat protein binds to ARGONAUTE 1 and suppresses the translation repression of a reporter gene. Mol Plant Microbe Interact, 2014, 27: 933-943 CrossRef Google scholar

[54]	Katiyar-AgarwalS, JinH. Role of small RNAs in host-microbe interactions. Annu Rev Phytopathol, 2010, 48: 225-246 CrossRef Google scholar

[55]	Katiyar-AgarwalS, MorganR, DahlbeckD, BorsaniO, VillegasA Jr, ZhuJK, StaskawiczBJ, JinH. A pathogen-inducible endogenous siRNA in plant immunity. Proc Natl Acad Sci U S A, 2006, 103: 18002-18007 CrossRef Google scholar

[56]	KisA, TholtG, IvanicsM, VárallyayÉ, JenesB, HaveldaZ. Polycistronic artificial miRNA-mediated resistance to wheat dwarf virus in barley is highly efficient at low temperature. Mol Plant Pathol, 2016, 17: 427-437 CrossRef Google scholar

[57]

KochA, BiedenkopfD, FurchA, WeberL, RossbachO, AbdellatefE, LinicusL, JohannsmeierJ, JelonekL, GoesmannA, CardozaV, McMillanJ, MentzelT, KogelK-H. An RNAi-based control of Fusarium graminearum infections through spraying of long dsRNAs involves a plant passage and is controlled by the fungal silencing machinery. PLoS Pathog, 2016, 12 CrossRef Google scholar

[58]	KochA, KumarN, WeberL, KellerH, ImaniJ, KogelK-H. Host-induced gene silencing of cytochrome P450 lanosterol C14 alpha-demethylase-encoding genes confers strong resistance to Fusarium species. Proc Natl Acad Sci U S A, 2013, 110: 19324-19329 CrossRef Google scholar

[59]	KreuzeJF, SavenkovEI, CuellarW, LiX, ValkonenJP. Viral class 1 RNase III involved in suppression of RNA silencing. J Virol, 2005, 79: 7227-7238 CrossRef Google scholar

[60]	KungYJ, LinSS, HuangYL, ChenTC, HarishSS, ChuaNH, YehSD. Multiple artificial microRNAs targeting conserved motifs of the replicase gene confer robust transgenic resistance to negative-sense single-stranded RNA plant virus. Mol Plant Pathol, 2012, 13: 303-317 CrossRef Google scholar

[61]	KuriharaY, WatanabeY. Arabidopsis micro-RNA biogenesis through Dicer-like 1 protein functions. Proc Natl Acad Sci U S A, 2004, 101: 12753-12758 CrossRef Google scholar

[62]	KwakSY, LewTTS, SweeneyCJ, KomanVB, WongMH, Bohmert-TatarevK, SnellKD, SeoJS, ChuaNH, StranoMS. Chloroplast-selective gene delivery and expression in planta using chitosan-complexed single-walled carbon nanotube carriers. Nat Nanotechnol, 2019, 14: 447-455 CrossRef Google scholar

[63]	LiCF, PontesO, El-ShamiM, HendersonIR, BernatavichuteYV, ChanSW, LagrangeT, PikaardCS, JacobsenSE. An ARGONAUTE4-containing nuclear processing center colocalized with Cajal bodies in Arabidopsis thaliana. Cell, 2006, 126: 93-106 CrossRef Google scholar

[64]	LiF, PignattaD, BendixC, BrunkardJO, CohnMM, TungJ, SunH, KumarP, BakerB. MicroRNA regulation of plant innate immune receptors. Proc Natl Acad Sci U S A, 2012, 109: 1790-1795 CrossRef Google scholar

[65]	LiXP, MaXC, WangH, ZhuY, LiuXX, LiTT, ZhengYP, ZhaoJQ, ZhangJW, HuangYY, PuM, FengH, FanJ, LiY, WangWM. Osa-miR162a fine-tunes rice resistance to Magnaporthe oryzae and yield. Rice (N Y), 2020, 13: 38 CrossRef Google scholar

[66]

LiY, CaoXL, ZhuY, YangXM, ZhangKN, XiaoZY, WangH, ZhaoJH, ZhangLL, LiGB, ZhengYP, FanJ, WangJ, ChenXQ, WuXJ, ZhaoJQ, DongOX, ChenXW, ChernM, WangWM. Osa-miR398b boosts H2O2 production and rice blast disease-resistance via multiple superoxide dismutases. New Phytol, 2019, 222: 1507-1522 CrossRef Google scholar

[67]

LiY, SunQ, ZhaoT, XiangH, ZhangX, WuZ, ZhouC, ZhangX, WangY, ZhangY, WangX, LiD, YuJ, Dinesh-KumarSP, HanC. Interaction between Brassica yellows virus silencing suppressor P0 and plant SKP1 facilitates stability of P0 in vivo against degradation by proteasome and autophagy pathways. New Phytol, 2019, 222: 1458-1473 CrossRef Google scholar

[68]	LiY, ZhangQ, ZhangJ, WuL, QiY, ZhouJM. Identification of microRNAs involved in pathogen-associated molecular pattern-triggered plant innate immunity. Plant Physiol, 2010, 152: 2222-2231 CrossRef Google scholar

[69]	LiY, ZhaoSL, LiJL, HuXH, WangH, CaoXL, XuYJ, ZhaoZX, XiaoZY, YangN, FanJ, HuangF, WangWM. Osa-miR169 negatively regulates rice immunity against the blast fungus Magnaporthe oryzae. Front Plant Sci, 2017, 8: 2 CrossRef Google scholar

[70]	Li W, Deng YW, Ning YS, He ZH, Wang GL (2020a) Exploiting broad-spectrum disease resistance in crops: from molecular dissection to breeding. Annu Rev Plant Biol 71:575–603. https://doi.org/10.1146/annurev-arplant-010720-022215

[71]	LiuJ, ChengX, LiuD, XuW, WiseR, ShenQH. The miR9863 family regulates distinct Mla alleles in barley to attenuate NLR receptor-triggered disease resistance and cell-death signaling. PLoS Genet, 2014, 10 CrossRef Google scholar

[72]	LiuM, ShiZ, ZhangX, WangM, ZhangL, ZhengK, LiuJ, HuX, DiC, QianQ, HeZ, YangDL. Inducible overexpression of ideal plant Architecture1 improves both yield and disease resistance in rice. Nat Plants, 2019, 5: 398-400 CrossRef Google scholar

[73]	Liu P, Zhang X, Zhang F, Xu M, Ye Z, Wang K, Liu S, Han X, Cheng Y, Zhong K, Zhang T, Li L, Ma Y, Chen M, Chen J, Yang J (2021) A virus-derived siRNA activates plant immunity by interfering with ROS scavenging. Mol Plant. https://doi.org/10.1016/j.molp.2021.03.022

[74]	LiuJ, ZhangT, JiaJ, SunJ. The wheat mediator subunit TaMED25 interacts with the transcription factor TaEIL1 to negatively regulate disease resistance against powdery mildew. Plant Physiol, 2016, 170: 1799 CrossRef Google scholar

[75]	LuJ, YangX, ChenJ, LiT, LiY. Osa-miR439 negatively regulates rice immunity against Magnaporthe oryzae. Ric Sci, 2021, 28: 156-165 CrossRef Google scholar

[76]	LuS, SunYH, AmersonH, ChiangVL. MicroRNAs in loblolly pine (Pinus taeda L.) and their association with fusiform rust gall development. Plant J, 2007, 51: 1077-1098 CrossRef Google scholar

[77]	MaC, LuY, BaiS, ZhangW, DuanX, MengD, WangZ, WangA, ZhouZ, LiT. Cloning and characterization of miRNAs and their targets, including a novel miRNA-targeted NBS-LRR protein class gene in apple (Golden delicious). Mol Plant, 2014, 7: 218-230 CrossRef Google scholar

[78]	MaS, LapinD, LiuL, SunY, SongW, ZhangX, LogemannE, YuD, WangJ, JirschitzkaJ, HanZ, Schulze-LefertP, ParkerJE, ChaiJ. Direct pathogen-induced assembly of an NLR immune receptor complex to form a holoenzyme. Science, 2020, 370: eabe3069 CrossRef Google scholar

[79]	McLoughlinAG, WytinckN, WalkerPL, GirardIJ, RashidKY, de KievitT, FernandoWGD, WhyardS, BelmonteMF. Identification and application of exogenous dsRNA confers plant protection against Sclerotinia sclerotiorum and Botrytis cinerea. Sci Rep, 2018, 8: 7320 CrossRef Google scholar

[80]	Melech-BonfilS, SessaG. Tomato MAPKKKε is a positive regulator of cell-death signaling networks associated with plant immunity. Plant J, 2010, 64: 379-391 CrossRef Google scholar

[81]	MitterN, ZhaiY, BaiAX, ChuaK, EidS, ConstantinM, MitchellR, PappuHR. Evaluation and identification of candidate genes for artificial microRNA-mediated resistance to tomato spotted wilt virus. Virus Res, 2016, 211: 151-158 CrossRef Google scholar

[82]	MoscouMJ, BogdanoveAJ. A simple cipher governs DNA recognition by TAL effectors. Science, 2009, 326: 1501 CrossRef Google scholar

[83]	NatarajanB, KalsiHS, GodboleP, MalankarN, ThiagarayaselvamA, SiddappaS, ThulasiramHV, ChakrabartiSK, BanerjeeAK. MiRNA160 is associated with local defense and systemic acquired resistance against Phytophthora infestans infection in potato. J Exp Bot, 2018, 69: 2023-2036 CrossRef Google scholar

[84]	NavarroL, DunoyerP, JayF, ArnoldB, DharmasiriN, EstelleM, VoinnetO, JonesJD. A plant miRNA contributes to antibacterial resistance by repressing auxin signaling. Science, 2006, 312: 436-439 CrossRef Google scholar

[85]	NgouBPM, AhnHK, DingP, JonesJDG. Mutual potentiation of plant immunity by cell-surface and intracellular receptors. Nature, 2021, 592: 110-115 CrossRef Google scholar

[86]	NiuQW, LinSS, ReyesJL, ChenKC, WuHW, YehSD, ChuaNH. Expression of artificial microRNAs in transgenic Arabidopsis thaliana confers virus resistance. Nat Biotechnol, 2006, 24: 1420-1428 CrossRef Google scholar

[87]	NowaraD, GayA, LacommeC, ShawJ, RidoutC, DouchkovD, HenselG, KumlehnJ, SchweizerP. HIGS: host-induced gene silencing in the obligate biotrophic fungal pathogen Blumeria graminis. Plant Cell, 2010, 22: 3130-3141 CrossRef Google scholar

[88]	PadmanabhanC, ZhangX, JinH. Host small RNAs are big contributors to plant innate immunity. Curr Opin Plant Biol, 2009, 12: 465-472 CrossRef Google scholar

[89]	PeragineA, YoshikawaM, WuG, AlbrechtHL, PoethigRS. SGS3 and SGS2/SDE1/RDR6 are required for juvenile development and the production of trans-acting siRNAs in Arabidopsis. Genes Dev, 2004, 18: 2368-2379 CrossRef Google scholar

[90]	PontesO, LiCF, Costa NunesP, HaagJ, ReamT, VitinsA, JacobsenSE, PikaardCS. The Arabidopsis chromatin-modifying nuclear siRNA pathway involves a nucleolar RNA processing center. Cell, 2006, 126: 79-92 CrossRef Google scholar

[91]	PrasadA, SharmaN, MuthamilarasanM, RanaS, PrasadM. Recent advances in small RNA mediated plant-virus interactions. Crit Rev Biotechnol, 2019, 39: 587-601 CrossRef Google scholar

[92]	PurkayasthaA, DasguptaI. Virus-induced gene silencing: a versatile tool for discovery of gene functions in plants. Plant Physiol Biochem, 2009, 47: 967-976 CrossRef Google scholar

[93]	PurringtonCB. Costs of resistance. Curr Opin Plant Biol, 2000, 3: 305-308 CrossRef Google scholar

[94]

Qiao L, Lan C, Capriotti L, Ah-Fong A, Nino Sanchez J, Hamby R, Heller J, Zhao H, Louise Glass N, Judelson HS, Mezzetti B, Niu D, Jin H (2021) Spray-induced gene silencing for disease control is dependent on the efficiency of pathogen RNA uptake. Plant Biotechnol J. https://doi.org/10.1094/PHYTO-02-21-0054-SC

[95]	QiaoL, ZhengL, ShengC, ZhaoH, JinH, NiuD. Rice siR109944 suppresses plant immunity to sheath blight and impacts multiple agronomic traits by affecting auxin homeostasis. Plant J, 2020, 102: 948-964 CrossRef Google scholar

[96]	QiaoY, LiuL, XiongQ, FloresC, WongJ, ShiJ, WangX, LiuX, XiangQ, JiangS, ZhangF, WangY, JudelsonHS, ChenX, MaW. Oomycete pathogens encode RNA silencing suppressors. Nat Genet, 2013, 45: 330-333 CrossRef Google scholar

[97]	QiaoY, ShiJ, ZhaiY, HouY, MaW. Phytophthora effector targets a novel component of small RNA pathway in plants to promote infection. Proc Natl Acad Sci U S A, 2015, 112: 5850-5855 CrossRef Google scholar

[98]	RanjanA, JayaramanD, GrauC, HillJH, WhithamSA, AnéJM, SmithDL, KabbageM. The pathogenic development of Sclerotinia sclerotiorum in soybean requires specific host NADPH oxidases. Mol Plant Pathol, 2018, 19: 700-714 CrossRef Google scholar

[99]	RegenteM, PinedoM, ClementeHS, BalliauT, JametE, de la CanalL. Plant extracellular vesicles are incorporated by a fungal pathogen and inhibit its growth. J Exp Bot, 2017, 68: 5485-5495 CrossRef Google scholar

[100]

RichardMMS, GratiasA, MeyersBC, GeffroyV. Molecular mechanisms that limit the costs of NLR-mediated resistance in plants. Mol Plant Pathol, 2018, 19: 2516-2523 CrossRef Google scholar

[101]

RosaC, KuoYW, WuriyanghanH, FalkBW. RNA interference mechanisms and applications in plant pathology. Annu Rev Phytopathol, 2018, 56: 581-610 CrossRef Google scholar

[102]

Ruiz-FerrerV, VoinnetO. Roles of plant small RNAs in biotic stress responses. Annu Rev Plant Biol, 2009, 60: 485-510 CrossRef Google scholar

[103]

Salvador-GuiraoR, HsingYI, San SegundoB. The polycistronic miR166k-166h positively regulates rice immunity via post-transcriptional control of EIN2. Front Plant Sci, 2018, 9: 337 CrossRef Google scholar

[104]

SangH, KimJ-I. Advanced strategies to control plant pathogenic fungi by host-induced gene silencing (HIGS) and spray-induced gene silencing (SIGS). Plant Biotechnol Rep, 2020, 14: 1-8 CrossRef Google scholar

[105]

ScofieldSR, HuangL, BrandtAS, GillBS. Development of a virus-induced gene-silencing system for hexaploid wheat and its use in functional analysis of the Lr21-mediated leaf rust resistance pathway. Plant Physiol, 2005, 138: 2165-2173 CrossRef Google scholar

[106]

ShivaprasadPV, ChenHM, PatelK, BondDM, SantosBA, BaulcombeDC. A microRNA superfamily regulates nucleotide binding site-leucine-rich repeats and other mRNAs. Plant Cell, 2012, 24: 859-874 CrossRef Google scholar

[107]

SilhavyD, MolnárA, LucioliA, SzittyaG, HornyikC, TavazzaM, BurgyánJ. A viral protein suppresses RNA silencing and binds silencing-generated, 21- to 25-nucleotide double-stranded RNAs. EMBO J, 2002, 21: 3070-3080 CrossRef Google scholar

[108]

SongX, LiY, CaoX, QiY. MicroRNAs and their regulatory roles in plant-environment interactions. Annu Rev Plant Biol, 2019, 70: 489-525 CrossRef Google scholar

[109]

SongY, ThommaB. Host-induced gene silencing compromises Verticillium wilt in tomato and Arabidopsis. Mol Plant Pathol, 2018, 19: 77-89 CrossRef Google scholar

[110]

SpoelSH, DongX. How do plants achieve immunity? Defence without specialized immune cells. Nat Rev Immunol, 2012, 12: 89-100 CrossRef Google scholar

[111]

ThinesM. Oomycetes. Curr Biol, 2018, 28: R812-R813 CrossRef Google scholar

[112]

TianW, HouC, RenZ, WangC, ZhaoF, DahlbeckD, HuS, ZhangL, NiuQ, LiL, StaskawiczBJ, LuanS. A calmodulin-gated calcium channel links pathogen patterns to plant immunity. Nature, 2019, 572: 131-135 CrossRef Google scholar

[113]

TortiS, SchlesierR, ThümmlerA, BartelsD, RömerP, KochB, WernerS, PanwarV, KanyukaK, WirénNV, JonesJDG, HauseG, GiritchA, GlebaY. Transient reprogramming of crop plants for agronomic performance. Nat Plants, 2021, 7: 159-171 CrossRef Google scholar

[114]

VoinnetO. Origin, biogenesis, and activity of plant microRNAs. Cell, 2009, 136: 669-687 CrossRef Google scholar

[115]

WangH, JiaoX, KongX, HameraS, WuY, ChenX, FangR, YanY. A signaling cascade from miR444 to RDR1 in rice antiviral RNA silencing pathway. Plant Physiol, 2016, 170: 2365-2377 CrossRef Google scholar

[116]

WangH, LiY, ChernM, ZhuY, ZhangLL, LuJH, LiXP, DangWQ, MaXC, YangZR, YaoSZ, ZhaoZX, FanJ, HuangYY, ZhangJW, PuM, WangJ, HeM, LiWT, ChenXW, WuXJ, LiSG, LiP, LiY, RonaldPC, WangWM. Suppression of rice miR168 improves yield, flowering time and immunity. Nat Plants, 2021, 7: 129-136 CrossRef Google scholar

[117]

WangJ, HuM, WangJ, QiJ, HanZ, WangG, QiY, WangHW, ZhouJM, ChaiJ. Reconstitution and structure of a plant NLR resistosome conferring immunity. Science, 2019, 364: eaav5870 CrossRef Google scholar

[118]

WangJ, WangJ, HuM, WuS, QiJ, WangG, HanZ, QiY, GaoN, WangHW, ZhouJM, ChaiJ. Ligand-triggered allosteric ADP release primes a plant NLR complex. Science, 2019, 364: eaav5868 CrossRef Google scholar

[119]

WangM, WeibergA, DellotaE Jr, YamaneD, JinH. Botrytis small RNA Bc-siR37 suppresses plant defense genes by cross-kingdom RNAi. RNA Biol, 2017, 14: 421-428 CrossRef Google scholar

[120]

WangM, WeibergA, LinFM, ThommaBP, HuangHD, JinH. Bidirectional cross-kingdom RNAi and fungal uptake of external RNAs confer plant protection. Nat Plants, 2016, 2: 16151 CrossRef Google scholar

[121]

WangW, GaliliG. Tuning the orchestra: miRNAs in plant immunity. Trends Plant Sci, 2019, 24: 189-191 CrossRef Google scholar

[122]

Wang Z, Xia Y, Lin S, Wang Y, Guo B, Song X, Ding S, Zheng L, Feng R, Chen S, Bao Y, Sheng C, Zhang X, Wu J, Niu D, Jin H, Zhao H (2018) Osa-miR164a targets OsNAC60 and negatively regulates rice immunity against the blast fungus Magnaporthe oryzae. Plant J:584–597. https://doi.org/10.1111/tpj.13972

[123]

WeibergA, WangM, BellingerM, JinH. Small RNAs: a new paradigm in plant-microbe interactions. Annu Rev Phytopathol, 2014, 52: 495-516 CrossRef Google scholar

[124]

WeibergA, WangM, LinFM, ZhaoH, ZhangZ, KaloshianI, HuangHD, JinH. Fungal small RNAs suppress plant immunity by hijacking host RNA interference pathways. Science, 2013, 342: 118-123 CrossRef Google scholar

[125]

WernerBT, GaffarFY, SchuemannJ, BiedenkopfD, KochAM. RNA-spray-mediated silencing of Fusarium graminearum AGO and DCL genes improve barley disease resistance. Front Plant Sci, 2020, 11: 476 CrossRef Google scholar

[126]

WongJ, GaoL, YangY, ZhaiJ, ArikitS, YuY, DuanS, ChanV, XiongQ, YanJ, LiS, LiuR, WangY, TangG, MeyersBC, ChenX, MaW. Roles of small RNAs in soybean defense against Phytophthora sojae infection. Plant J, 2014, 79: 928-940 CrossRef Google scholar

[127]

WuJ, YangR, YangZ, YaoS, ZhaoS, WangY, LiP, SongX, JinL, ZhouT, LanY, XieL, ZhouX, ChuC. ROS accumulation and antiviral defence control by microRNA528 in rice. Nat Plants, 2017, 3: 16203 CrossRef Google scholar

[128]

WuL, ZhouH, ZhangQ, ZhangJ, NiF, LiuC, QiY. DNA methylation mediated by a microRNA pathway. Mol Cell, 2010, 38: 465-475 CrossRef Google scholar

[129]

XieS, YuH, LiE, WangY, LiuJ, JiangH. Identification of miRNAs involved in Bacillus velezensis FZB42-activated induced systemic resistance in maize. Int J Mol Sci, 2019, 20: 5057 CrossRef Google scholar

[130]

XiongQ, YeW, ChoiD, WongJ, QiaoY, TaoK, WangY, MaW. Phytophthora suppressor of RNA silencing 2 is a conserved RxLR effector that promotes infection in soybean and Arabidopsis thaliana. Mol Plant Microbe Interact, 2014, 27: 1379-1389 CrossRef Google scholar

[131]

XuW, MengY, WiseRP. Mla- and Rom1-mediated control of microRNA398 and chloroplast copper/zinc superoxide dismutase regulates cell death in response to the barley powdery mildew fungus. New Phytol, 2014, 201: 1396-1412 CrossRef Google scholar

[132]

YangLP, FangYY, AnCP, DongL, ZhangZH, ChenH, XieQ, GuoHS. C2-mediated decrease in DNA methylation, accumulation of siRNAs, and increase in expression for genes involved in defense pathways in plants infected with beet severe curly top virus. Plant J, 2013, 73: 910-917 CrossRef Google scholar

[133]

YaoS, YangZ, YangR, HuangY, GuoG, KongX, LanY, ZhouT, WangH, WangW, CaoX, WuJ, LiY. Transcriptional regulation of miR528 by OsSPL9 orchestrates antiviral response in rice. Mol Plant, 2019, 12: 1114-1122 CrossRef Google scholar

[134]

YiH, RichardsEJ. A cluster of disease resistance genes in Arabidopsis is coordinately regulated by transcriptional activation and RNA silencing. Plant Cell, 2007, 19: 2929-2939 CrossRef Google scholar

[135]

YuanM, JiangZ, BiG, NomuraK, LiuM, WangY, CaiB, ZhouJM, HeSY, XinXF. Pattern-recognition receptors are required for NLR-mediated plant immunity. Nature, 2021, 592: 105-109 CrossRef Google scholar

[136]

ZhaiJ, JeongDH, De PaoliE, ParkS, RosenBD, LiY, GonzalezAJ, YanZ, KittoSL, GrusakMA, JacksonSA, StaceyG, CookDR, GreenPJ, SherrierDJ, MeyersBC. MicroRNAs as master regulators of the plant NB-LRR defense gene family via the production of phased, trans-acting siRNAs. Genes Dev, 2011, 25: 2540-2553 CrossRef Google scholar

[137]

ZhangH, TanX, LiL, HeY, HongG, LiJ, LinL, ChengY, YanF, ChenJ, SunZ. Suppression of auxin signalling promotes rice susceptibility to Rice black streaked dwarf virus infection. Mol Plant Pathol, 2019, 20: 1093-1104 CrossRef Google scholar

[138]

Zhang H, Tao Z, Hong H, Chen Z, Wu C, Li X, Xiao J, Wang S (2016a) Transposon-derived small RNA is responsible for modified function of WRKY45 locus. Nat Plants 2:16016. https://doi.org/10.1038/nplants.2016.16

[139]

ZhangLL, LiY, ZhengYP, WangH, YangX, ChenJF, ZhouSX, WangLF, LiXP, MaXC, ZhaoJQ, PuM, FengH, FanJ, ZhangJW, HuangYY, WangWM. Expressing a target mimic of miR156fhl-3p enhances rice blast disease resistance without yield penalty by improving SPL14 expression. Front Genet, 2020, 11: 327 CrossRef Google scholar

[140]

Zhang N, Luo J, Rossman AY, Aoki T, Chuma I, Crous PW, Dean R, de Vries RP, Donofrio N, Hyde KD, Lebrun MH, Talbot NJ, Tharreau D, Tosa Y, Valent B, Wang Z, Xu JR (2016b) Generic names in Magnaporthales. IMA Fungus 7:155–159. https://doi.org/10.5598/imafungus.2016.07.01.09

[141]

Zhang T, Zhao YL, Zhao JH, Wang S, Jin Y, Chen ZQ, Fang YY, Hua CL, Ding SW, Guo HS (2016c) Cotton plants export microRNAs to inhibit virulence gene expression in a fungal pathogen. Nat Plants 2:16153. https://doi.org/10.1038/nplants.2016.153

[142]

ZhangW, GaoS, ZhouX, ChellappanP, ChenZ, ZhouX, ZhangX, FromuthN, CoutinoG, CoffeyM, JinH. Bacteria-responsive microRNAs regulate plant innate immunity by modulating plant hormone networks. Plant Mol Biol, 2011, 75: 93-105 CrossRef Google scholar

[143]

ZhangX, BaoY, ShanD, WangZ, SongX, WangZ, WangJ, HeL, WuL, ZhangZ, NiuD, JinH, ZhaoH. Magnaporthe oryzae induces the expression of a microRNA to suppress the immune response in rice. Plant Physiol, 2018, 177: 352-368 CrossRef Google scholar

[144]

ZhaoM, CaiC, ZhaiJ, LinF, LiL, ShreveJ, ThimmapuramJ, HughesTJ, MeyersBC, MaJ. Coordination of microRNAs, phasiRNAs, and NB-LRR genes in response to a plant pathogen: insights from analyses of a set of soybean Rps gene near-isogenic lines. Plant Genome, 2015, 8: eplantgenome2014.2009.0044 CrossRef Google scholar

[145]

ZhaoYT, WangM, WangZM, FangRX, WangXJ, JiaYT. Dynamic and coordinated expression changes of rice small RNAs in response to Xanthomonas oryzae pv. Oryzae. J Genet Genomics, 2015, 42: 625-637 CrossRef Google scholar

[146]

ZhaoZX, FengQ, CaoXL, ZhuY, WangH, ChandranV, FanJ, ZhaoJQ, PuM, LiY, WangWM. Osa-miR167d facilitates infection of Magnaporthe oryzae in rice. J Integr Plant Biol, 2020, 62: 702-715 CrossRef Google scholar

[147]

ZhouJM, ZhangY. Plant immunity: danger perception and signaling. Cell, 2020, 181: 978-989 CrossRef Google scholar

[148]

ZhuQ, YuS, ZengD, LiuH, WangH, YangZ, XieX, ShenR, TanJ, LiH, ZhaoX, ZhangQ, ChenY, GuoJ, ChenL, LiuYG. Development of “purple endosperm rice” by engineering anthocyanin biosynthesis in the endosperm with a high-efficiency transgene stacking system. Mol Plant, 2017, 10: 918-929 CrossRef Google scholar

[149]

ZouB, DingY, LiuH, HuaJ. Silencing of copine genes confers common wheat enhanced resistance to powdery mildew. Mol Plant Pathol, 2018, 19: 1343-1352 CrossRef Google scholar